WO2003013049A1 - Distribution of sub-carriers of a multi-carrier system for low rate terminals - Google Patents

Abstract

The aim of the invention is to reduce the complexity of terminals which can only operate at low data rates. To achieve this, a terminal which is suitable for receiving a multi-carrier signal is fitted with a filter device which filters out at least one carrier of a data signal from several carriers of the received multi-carrier signal, whereupon subsequent signal processing in the terminal is significantly simplified. If a pilot signal is emitted on an additional carrier, the terminal (MT) can become synchronized with the base station, thereby avoiding inter carrier interference.

Description

description

Distribution of subcarriers of a multi-carrier system for low-rate terminals

The present invention relates to a receiving and transmitting device for a multicarrier system with which multicarrier signals can be received and transmitted. Furthermore, the present invention relates to corresponding reception and transmission methods and in particular terminals and base stations of multicarrier systems.

Broadband wireless transmission systems are often implemented as multi-carrier or multi-carrier systems. Examples of such systems are OFDM (Orthogonal Frequency Division Multiplex) based HiperLAN / 2 and IEEE 802.1l systems. Mobile terminals and other end devices which are capable of receiving, processing and transmitting high data rates are usually used in these systems. The construction of such end devices for high data rates is relatively complex.

If a terminal with a low data rate is to be operated on a multicarrier system, it must nevertheless be able to receive and process the multicarrier signals. This means that the implementation effort for these low-priced terminals is relatively high. The reason for this is that with the common multicarrier concepts, data is transmitted simultaneously on all carriers or subcarriers in a short slot or time slot. This means that the receiving and transmitting branch of a terminal must be able to serve all subcarriers, which increases its complexity.

The object of the present invention is therefore to reduce the complexity of terminals or terminals at low data rates e.g. B. work for voice transmission.

According to the invention, this object is achieved by a receiving device, in particular a terminal, for a multi-carrier system with a receiving device for receiving a multi-carrier signal and a filter device for filtering out at least one carrier from a plurality of carriers of the received multi-carrier signal.

The above-mentioned object is further achieved by a transmitting device, in particular a base station, for a multi-carrier system with a transmitting device for transmitting a multi-carrier signal with several carriers, several receivers each being able to assign one or more of the carriers of the multi-carrier signal.

In addition, the invention provides a method for receiving data signals by receiving a multicarrier signal with a plurality of carriers and filtering out at least one of the carriers of the received multicarrier signal which carries the data signal.

Finally, the invention provides a method for sending at least one data signal by sending the data signal in a multi-carrier signal with a plurality of carriers, at least one of the carriers of the multi-carrier system being assigned to a receiver, so that the data signal is transmitted to the receiver on the at least one carrier.

The complexity of a terminal or terminal can thus advantageously be reduced, since it no longer has to process a broadband multicarrier signal internally, but the relevant carrier or carriers are filtered out before processing.

In addition, several terminals can now be operated simultaneously from one base station. Advantageous further developments result from the subclaims.

The present invention will now be explained in more detail with reference to the accompanying drawings, in which:

1 shows a broadband cordless transmission system according to the prior art; and

2 shows a broadband wireless transmission system according to an embodiment of the present invention.

1, a base station, which is based on the OFDM concept, sends a transmission signal to a plurality of terminal devices or mobile terminals MTA, MTB, MTC and MTD. The transmission signal has several time slots A, B, C and D. All carriers or subcarriers are transmitted in each of the time slots. In the present case, a time slot is provided for a particular terminal. Time slot A is assigned to Terminal MTA, B to Terminal MTB, C to Terminal MTC and D to Terminal MTD. Each of the mobile terminals MTA, MTB, MTC and MTD receives the transmission signal in its entire bandwidth, processes it further and thus extracts the data relevant to it. Each of the mobile terminals must therefore be designed for broadband processing, even if only a voice connection needs to be established between the base station and the corresponding mobile terminal. This requires a high level of performance and complexity of the terminals, which ultimately also has an impact on their acquisition costs.

2 now shows the solution according to the invention in which the base station BS likewise sends a multi-carrier or multicarrier signal to mobile terminals MTa, MTb, MTc and MTd. In this case, however, the mobile terminals MTa, MTb, MTc and MTd are assigned to each carrier or sub-carrier pair a, b, c and d. This means that several mobile terminals can be addressed simultaneously in one time slot A. In principle, it is now possible for a terminal to be addressed with exactly one carrier. A base station could thus address a total of 52 low-rate terminals by sending a multicarrier signal with 52 subcarriers or carriers. In practice, however, implementation problems arise when multi-carrier signals are used too intensively for different end devices due to inter-carrier interference (ICI). The reason for such intercarrier interference is that the carrier frequencies used by the base station or the terminals can never be exactly the same. The frequency deviations could only be kept so low with very high expenditure on equipment that practically no more disturbances occur.

For economic reasons, however, it is cheaper to send pilot signals on defined carriers in a transmission slot or transmission time slot in order to keep the inter-carrier interference in this transmission slot as low as possible. The respective receivers can then use the pilot signals to match their carrier frequency to that of the base station. In addition to this frequency synchronization, the pilot signal can in principle also be used as a reference signal for time synchronization.

The synchronization therefore requires that in addition to a carrier for data signals, a carrier for a pilot signal is reserved for each terminal. This means that two carriers must be available in a time slot per terminal in order to avoid inter-carrier interference. In Fig. 2 each pair of carriers is shown as a single line. Thus, the four terminals MTa, MTb, MTc and MTd can be addressed by the four carrier pairs a, b, c and d in the time slot A of the multi-carrier signal from the base station BS. Each of the final devices filters out two carrier frequencies from the multicarrier signal in a narrow band and processes this signal pair further. Communication data is extracted from one carrier signal, while the pilot signal is extracted from the other carrier and used to determine the carrier frequency or carrier frequencies of the terminal with that of the base station

Synchronize BS. This means that data can be sent to several terminals without causing inter-carrier interference. It is fundamentally cheap, but not necessary, that the carriers for the pilot signal and data signal (e) lie next to one another in terms of frequency in order to take into account simple bandpass filtering in the terminal.

If several end devices are operated by the base station BS, it can be assumed that the processing capacities of the different end devices are different. The transmission capacity can therefore be better utilized if the number of carriers on which data is transmitted to the terminals can be varied for each addressed terminal. The number of carriers is thus advantageously dynamically adapted to the end devices in use or their data rate. For example, the terminal MTa with two carriers, i. H. one for the pilot signal and one for a data signal, the terminal MTb with three carriers, d. H. one for the pilot signal and two for data signals, the terminal MTc with four carriers, d. H. one for the pilot signal and three for data signals, etc. can be operated. The dynamic adaptation of the number of carriers for data signals to the processing rate of the respective terminals is necessary in order to avoid that all terminals are only supplied with the data rate that the slowest terminal can process.

The entry and exit of end devices with different data processing rates into and out of the multi-carrier system can be realized by dynamically assigning pilot signals to carriers or subcarriers. The dynamic allocation enables an optimal use of the transmission bandwidth, and thus communication with as many end devices as possible. At the same time, this concept enables the implementation complexity of a terminal or terminal device to be significantly reduced. A typical need for this is terminal equipment for voice transmission, so-called “voice terminals *, which with the present invention have relatively implemented with little complexity and in a hiper

LAN / 2 system can be operated.

LIST OF REFERENCE NUMBERS

MTA, MTB, MTC, MTD end devices or mobile terminals

A, B, C, D time slots

BS base station

MTa, MTb, MTc, MTd Mobile Terminals a, b, c, d carrier or subcarrier pair

Claims

claims

1. Receiving device, in particular a terminal, for a multicarrier system with a receiving device for receiving a multicarrier signal, a filter device for filtering out at least one carrier from several carriers of the received multicarrier signal.

2. Receiving device according to claim 1, wherein at least two carriers can be filtered out by the filter device, one of which carries a pilot signal for synchronizing the receiving device with the transmitter of the pilot signal.

3. Receiving device according to claim 1 or 2, wherein the multi-carrier system is based on OFDM and in particular on Hiper-LAN / 2 or IEEE 802.11a.

4. Receiving device according to one of claims 1 to 3, wherein the number of filterable carriers is dynamically variable.

5. Receiving device according to one of claims 1 to 4, further comprising a transmitting device for transmitting signals on at least one carrier, the frequency of which corresponds to that of the at least one received, filtered out carrier.

6. Transmitting device, in particular base station, for a multicarrier system with a transmitting device for transmitting a multicarrier signal with several carriers, characterized in that Several receivers can each be assigned one or more of the carriers of the multicarrier signal.

7. Transmitting device according to claim 6, wherein each of the receivers can be assigned at least two carriers, one of which carries a pilot signal which can be used for synchronization with the respective receiver.

8. Transmitting device according to claim 6 or 7, wherein the carriers are dynamically assignable to a receiver.

9. Transmitting device according to one of claims 6 to 8, wherein the number of carriers on which data can be transmitted to receivers can be dynamically adapted to a data rate of one or more receivers.

10.Procedure to receive data signals through

Reception of a multi-carrier signal with several carriers, g e k e n n e i c h n e t d u r c h

Filter out at least one of the carriers of the received

Multi-carrier signal that carries the data signal.

11. The method according to claim 10, wherein at least two carriers are filtered out during the filtering, one of which carries a pilot signal for synchronizing the transmitter and receiver.

12. The method according to claim 10, wherein the multicarrier signal is based on OFDM and in particular on HiperLAN / 2 or IEEE 802.11a.

13.The method according to any one of claims 10 to 12, wherein the number of carriers to be filtered out is varied dynamically.

14.The method according to any one of claims 10 to 13, wherein signals on at least one carrier, the frequency that of the at least one received, filtered out

Corresponds to the carrier.

15.Procedure to send at least one data signal

Sending the data signal in a multi-carrier signal with several carriers, g e k e n n e e i c h n e t d u r c h

Assigning at least one of the carriers of the multi-carrier system to a receiver so that the data signal is transmitted to the receiver on the at least one carrier.

16. The method according to claim 15, wherein at least two carriers are assigned to the receiver, one of the carriers carrying a pilot signal for synchronizing a transmitter with the receiver.

17. The method according to claim 15 or 16, wherein pilot signals are dynamically assigned to the carriers of the multicarrier signal.

18. The method according to any one of claims 15 to 17, wherein the number of carriers on which data is transmitted to a receiver are dynamically adapted to a predetermined data rate.